Semiconductor device with delay section

ABSTRACT

In a semiconductor memory device, a reference delay section has a first delay value and delays a first signal by a reference delay value obtained from the first delay value and an adjustment value while changing the adjustment value, and fixes the adjustment value when the first signal and the delayed first signal meet a predetermined condition. A delay section has a second delay value and generates an output signal based on a summation of the fixed adjustment value and the second delay value, and a set multiplication value in response to a trigger signal such that the output signal in an active state for a period corresponding to the set multiplication value.

CROSS REFERENCE TO RELATED APPLICATION

This application is a division of U.S. application Ser. No. 11/389,104filed on Mar. 27, 2006, which claimed priority under 35 USC 119 ofearlier Japanese application 2005-089420 filed on Mar. 25, 2005. Theentire contents of each of these earlier applications is herebyexpressly incorporated by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a semiconductor memory device, and inparticular, relates to a semiconductor memory device capable ofgenerating a delay signal.

2. Description of the Related Art

A semiconductor memory device is provided with a delay circuit. A delayamount by the delay circuit is determined through simulation at the timeof designing. However, an actual delay amount by the delay circuit isdifferent from the that of the delay circuit at the time of designing,due to diffusion conditions, in-plane variations in a wafer, and so on,at the time of manufacturing a semiconductor memory device.

It is desired to eliminate a difference between the delay amount of thedelay circuit at the time of designing, and the actual delay value ofthe delay circuit.

By the way, Japanese Laid Open Patent Application (JP-P2000-201058A)discloses a semiconductor device. The semiconductor device of thisconventional example is provided with a comparison delay circuitsection, a reference delay circuit section, a delay time determiningcircuit section, and a delay adjustment circuit section. The comparisondelay circuit section includes a delay circuit used to determinevariations of delay time. The reference delay circuit section includes adelay circuit in which at least one given reference delay time is set asa reference value of delay time. The delay time determining circuitsection determines the variations of delay time in the above comparisondelay circuit section, based on the reference delay time of thereference delay circuit section. The delay adjustment circuit sectionhaving a plurality of delay circuits each having different sets delaytime, selects one of the plurality of delay circuits in accordance withthe determination result of the delay time determining circuit section,to delay a desired signal. Consequently, it is possible to determine thevariations of delay time in the delay circuit caused by processvariations and so on, and adjust the delay time in accordance with thevariations.

Also, Japanese Laid Open Patent Application (JP-P2001-33529A) disclosesa delay clock generating device for generating a delayed clock signalhaving a given delay amount. The delay clock generating device isprovided with a period delay section, a half-period delay section, and ahigh-resolution delay section. The period delay section generates adelay amount corresponding to a reference clock period obtained bymultiplying an integer number, the reference clock period being shorterthan the given delay amount. The half-period delay section generates adelay amount of a half period of the reference clock signal. Thehigh-resolution delay section adds a differential delay amount betweenthe sum of delay amounts generated by the period delay section and thehalf-period delay section, and a given delay amount, to the delay amountgenerated by the period delay section and the half-period delay section.Consequently, it is possible to reduce a delay amount generated by thehigh-resolution delay section.

Also, Japanese Laid Open Patent Application (JP-P2002-76858A) disclosesa timing signal generating circuit. The timing signal generating circuitof this conventional example is provided with a plurality of first delayelements, a first selecting section, a generating section, a seconddelay element, a detecting section, a comparing section, a specifyingsection, and a control section. The plurality of first delay elementsare connected in series. The first selecting section selects one of theplurality of first delay signals outputted from the plurality of firstdelay elements. The generating section generates a timing signal basedon the first delay signal selected by the first selecting section. Thesecond delay element has the same delay characteristic as the firstdelay element. The detecting section detects N times (N is an integernumber) of the delay time of the second delay element. The comparingsection compares a detection time of the detecting section with areference time. The specifying section specifies a value of the N wherethe detection time and the reference time are in a given relationshipbased on the comparing result of the detecting section. The controlsection controls the first selecting section to select the first delaysignal that is relevant to a value specified by the specifying section.Consequently, it is possible to compensate a temperature dependencycharacteristic of a delay element.

Also, Japanese Laid Open Patent Application (JP-A-Heisei 8-274602)discloses a variable delay circuit. The variable delay circuit of thisconventional example is provided with a plurality of buses formed byserial connecting an optional number of variable delay gates, a busselecting section, a reference delay time generating section, a phasecomparing section, and a control signal generating section. The busselecting section selectively connects the plurality of buses and sets agiven delay time. The reference delay time generating section isarranged closely to the plurality of buses, and is formed by seriallyconnecting the variable delay gates, which are the same variable delaygates used for the plurality of buses, and delays a reference clocksignal by one period. The phase comparing section performs phasecomparison of the reference clock signal and a delay output of thereference delay time generating section. The control signal generatingsection converts an output of the phase comparing section into a delaytime control signal of the variable delay gate. The variable delaycircuit simultaneously controls the variable delay gates of thereference delay time generating section in response to the delay timecontrol signal. Consequently, it is possible to automatically compensatea variation of delay time caused by manufacturing variations.

Also, Japanese Laid Open Patent Application (JP-P2003-32104A) disclosesa DLL circuit. The DLL circuit of this conventional example is providedwith a basic phase comparator, a delay circuit, and a delay controlcircuit. The basic phase comparator detects a basic phase difference oftwo input signals. The delay control circuit receives an output signalof the basic phase comparator to adjust a delay amount of the delaycircuit. The DLL circuit provides at least one phase comparator fordetecting another phase difference different from the basic phasedifference, and changes a change amount of a delay amount in accordancewith the basic phase difference. Consequently, it is possible to reducea time during which delay amounts converge (locked) at a desired delayvalue.

Also, Japanese Laid Open Patent Application (JP-A-Heisei 9-304484)discloses a synchronous semiconductor memory device. The synchronoussemiconductor memory device of this conventional example is providedwith a reference delay circuit, a determining section, and a selectingsection. The reference delay circuit receives an external synchronoussignal, and outputs one or a plurality of delay signals for defining adelay design value. The determining section determines a position of ashift edge for defining a cycle time of the external synchronous signal,in comparison with a shift edge of one or a plurality of delay outputsignals of the reference delay circuit. The selecting section variablyselects a delay value for delaying an internal clock signal inaccordance with the magnitude relationship between an actual delay valueand a design value of the delay circuit based on the determinationresult. The selecting section sets a delay value to shorter or longerside in accordance with the fact that a delay value of the referencedelay circuit is larger or smaller than a design value, the delay valuedelaying the internal clock signal. Consequently, it is possible toautomatically set a change in a delay value caused by process change atmanufacturing, to an optimum value at the time of mode register settingof initial setting.

SUMMARY OF THE INVENTION

An object of the present invention is to provide a semiconductor memorydevice which can eliminates a difference between a delay value of adelay circuit at the time of designing and a delay value of an actualdelay circuit.

Another object of the present invention is to provide a semiconductormemory device which can obtain a desired delay value.

In an aspect of the present invention, a semiconductor memory deviceincludes a reference delay section having a first delay value andconfigured to delay a first signal by a reference delay value obtainedfrom the first delay value and an adjustment value while changing theadjustment value, and to fix the adjustment value when the first signaland the delayed first signal meet a predetermined condition; and a delaysection having a second delay value, and configured to generate anoutput signal based on a summation of the fixed adjustment value and thesecond delay value, and a set multiplication value in response to atrigger signal such that the output signal in an active state for aperiod corresponding to the set multiplication value.

Here, the predetermined condition may be coincidence of a phase of thefirst signal and a phase of the delayed first signal.

Also, the reference delay section may include a control pulse signalgenerating circuit configured to generate a clock pulse signal when thefirst signal and the delayed first signal do not meet the predeterminedcondition; and a counter circuit configured to count the clock pulsesignal to change the adjustment value.

In this case, the control pulse signal generating circuit may stop thegeneration of the clock pulse signal when the first signal and thedelayed first signal meet the predetermined condition, and the countercircuit may hold and fix the adjustment value when the clock pulsesignal is not supplied from the control pulse signal generating circuit.

Also, the second delay value is same as the first delay value.

Also, the delay section may include a control circuit configured to holdthe output signal to the active state in response to the trigger signal,and to reset the output signal to an inactive state when the summationof the fixed adjustment value and the second delay value is equal to theset multiplication value.

In this case, the delay section may include a delay circuit configuredto delay the output signal by the summation of the fixed adjustmentvalue and the second delay value; a delay counter configured to count anumber of times of the delay by the delay circuit; and a coincidencedetection circuit configured to generate a coincidence signal whendetecting coincidence of a count value of the delay counter and the setmultiplication value. The control circuit resets the output signal tothe inactive state in response to the coincidence signal.

Also, the semiconductor memory device may further include a plurality ofdelay sections. The reference delay section outputs the fixed adjustmentvalue to the plurality of delay sections, and the plurality of delaysections receives a plurality of set multiplication values which aredifferent from each other.

Also, in another aspect of the present invention, a method of generatingan output signal with a desired delay in a semiconductor memory deviceis achieved by delaying a first signal by a reference delay valueobtained from a first delay value and an adjustment value while changingthe adjustment value; by fixing the adjustment value when the firstsignal and the delayed first signal meet a predetermined condition; andby generating an output signal based on a summation of the fixedadjustment value and the second delay value, and a set multiplicationvalue in response to a trigger signal such that the output signal in anactive state for a period corresponding to the set multiplication value.

Also, the predetermined condition may be coincidence of a phase of thefirst signal and a phase of the delayed first signal.

Also, the delaying a first signal may be achieved by generating a clockpulse signal when the first signal and the delayed first signal do notmeet the predetermined condition; and by counting the clock pulse signalto change the adjustment value.

In this case, the fixing may be achieved by stopping the generation ofthe clock pulse signal when the first signal and the delayed firstsignal meet the predetermined condition; and by holding and fixing theadjustment value when the clock pulse signal is not supplied from thecontrol pulse signal generating circuit.

Also, the second delay value may be same as the first delay value.

Also, the generating an output signal may be achieved by holding theoutput signal to the active state in response to the trigger signal; andby resetting the output signal to an inactive state when the summationof the fixed adjustment value and the second delay value is equal to theset multiplication value.

Also, the generating an output signal may be achieved by furtherdelaying the output signal by the summation of the fixed adjustmentvalue and the second delay value; counting a number of times of thedelay by the delay circuit; and generating a coincidence signal whendetecting coincidence of a count value of the delay counter and the setmultiplication value. The resetting is achieved by resetting the outputsignal to the inactive state in response to the coincidence signal.

Also, the delaying and the fixing are carried out in a single referencedelay section, and the generating an output signal is carried out ineach of a plurality of delay sections. The plurality of delay sectionsreceives a plurality of set multiplication values which are differentfrom each other.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram showing the configuration of a semiconductormemory device according to a first embodiment of the present invention;

FIG. 2 is a circuit diagram showing the configuration of a referencedelay section in the semiconductor memory device according to the firstembodiment, when n is 3;

FIG. 3 is a circuit diagram showing the configuration of the delaysection in the semiconductor memory device according to the firstembodiment, when n is 3 and m is 3;

FIGS. 4A to 4K are timing charts showing an operation of the referencedelay section;

FIGS. 5A to 5G are timing charts showing an operation of the delaysection;

FIG. 6 is a block diagram showing the configuration of the semiconductormemory device according to a second embodiment of the present invention;

FIGS. 7A to 7G are timing charts showing an operation of a delaygenerating section DL0 in the semiconductor memory device in the secondembodiment;

FIGS. 8A to 8G are timing charts showing an operation of a delaygenerating section DL1 in the semiconductor memory device in the secondembodiment; and

FIGS. 9A to 9G are timing charts showing an operation of a delaygenerating section DLs in the semiconductor memory device in the secondembodiment.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Hereinafter, a semiconductor memory device of the present invention willbe described in detail with reference to the attached drawings.

First Embodiment

FIG. 1 is a block diagram showing a configuration of a semiconductormemory device according to the first embodiment of the presentinvention. Referring to FIG. 1, the semiconductor memory device in thefirst embodiment of the present invention has a reference delay sectionS0 and a delay section S1. The reference delay section S0 generates areference delay value. The delay section S1 outputs an output signalOUTPS with a delay value m times (m is an integer number equal to ormore than 1) of the reference delay value for a trigger signal INPS. Thereference delay section S0 has a reference circuit pulse generatingcircuit A1, a delay circuit A2, a determining circuit A3, a countercircuit A4, and a counter circuit control pulse signal generatingcircuit A5. The delay section S1 has a delay circuit control circuit A6,a delay circuit A7, a delay counter circuit A8, and a coincidencedetecting circuit A9. The delay circuit A7 has the same structure as thedelay circuit A2.

The reference delay section S0 is further provided with a PULSEIterminal, a TDEN terminal, an RST terminal, and CNT<n:0> terminals. Apulse signal PULSEI is supplied to the PULSEI terminal from ahigh-performance tester and so on. The pulse width of the pulse signalPULSEI in an active state indicates a set delay value. An enable signalTDEN generated based on an external command is supplied externally tothe TDEN terminal. A reset signal RST is supplied externally to the RSTterminal. The CNT <n:0> terminals are connected to the delay section S1through a bus. The delay circuit pulse generating circuit A1 receivesthe pulse signal PULSEI and the enable signal TDEN, and outputs anoutput signal DLYI to the delay circuit A2. If the pulse signal PULSEIis in the active state when the enable signal TDEN is supplied, thedelay circuit pulse generating circuit A1 outputs the delay signal DLYIin the active state to the delay circuit A2.

The delay circuit A2 receives the output signal DLYI outputted from thedelay circuit pulse generating circuit A1 and the bus signal CNT <n:0>,which is a count value outputted from the counter circuit A4, andoutputs an output signal DLYOB to the determining circuit A3. The value“n” of the bus signal CNT <n:0> is determined based on an adjustmentrange and adjustment accuracy of the delay circuit A2. The value n isobtained by subtracting one from an exponent when a combination isexpressed in an exponential form of 2. The delay circuit A2 resets anoutput signal DLYOB in response to the reset signal RST. The delaycircuit A2 has a first delay value. The delay circuit A2 generates asecond delay value based on the first delay value and an adjustmentvalue which is indicated based on the bus signal CNT <n:0>, and delaysthe output signal DLYI based on the second delay value to output theoutput signal DLYOB.

The determining circuit A3 receives the output signal DLYOB from thedelay circuit A2 and the pulse signal PULSEI, and outputs adetermination resultant signal DSTE to the counter circuit control pulsesignal generating circuit A5. The determining circuit A3 resets thedetermination resultant signal DSTE in response to the reset signal RST.The determining circuit A3 compares the second value and the set delayvalue in accordance with the pulse signal PULSEI and the signal DLYOBfrom the delay circuit A2. When the pulse width of the pulse signalPULSEI in the active state and a pulse width of the signal DLYOB in theactive state are not coincident with each other, the determining circuitA3 outputs the comparison result DSTE to indicate non-coincidencebetween the second delay value and the set delay value. When the pulsewidth of the pulse signal PULSEI in the active state and the pulse widthof the signal DLYOB in the active state are coincident with each other,the determining circuit A3 outputs the comparison result DSTE toindicate the coincidence between the second delay value and the setdelay value.

The counter circuit control pulse signal generating circuit A5 receivesthe determination resultant signal DSTE outputted from the determiningcircuit A3, the pulse signal PULSEI, and the enable signal TDEN, andoutputs a control pulse signal FFCK to the counter circuit A4. When thecomparison result DSTE indicates the non-coincidence between the seconddelay value and the set delay value, the counter circuit control pulsesignal generating circuit A5 outputs the control pulse signal FFCK inthe active state. On the other hand, when the comparison result DSTEindicates the coincidence between the second delay value and the setdelay value, the counter circuit control pulse signal generating circuitA5 outputs the control pulse signal FFCK in an inactive state, in orderto fix the adjustment value by the bus signal CNT <n:0> outputted fromthe counter circuit A4.

The counter circuit A4 receives the control pulse signal FFCK outputtedfrom the counter circuit control pulse signal generating circuit A5, andoutputs the bus signal CNT <n:0> to the delay circuits A2 and A7. Thebus signal CNT <n:0> is an adjustment count value for controlling thedelay values of the delay circuits A2 and A7. The counter circuit A4resets the count value in response to the reset signal RST. The countercircuit A4 retains the bus signal CNT <n:0> indicating the adjustmentvalue. When the control pulse signal FFCK is in the active state, thecounter circuit A4 increments the retained adjustment value by one, andoutputs the bus signal CNT <n:0> indicating the incremented adjustmentvalue. On the other hand, when the control pulse signal FFCK is in theinactive state, the counter circuit A4 regards the retained adjustmentvalue as a fixed adjustment value, and outputs the bus signal CNT <n:0>to indicate the fixed adjustment value. When the adjustment value isfixed, the delay circuit A2 generates the reference delay value based onthe first delay value and the adjustment value which is indicated basedon the fixed bus signal CNT <n;0>, and delays the output signal DLYIbased on the reference delay value to output the signal DLYOB.Consequently, in the semiconductor memory device of the presentinvention, it is possible to eliminate a difference between the delayvalue of the delay circuit at the time of designing and the delay valueof the actual delay circuit by using the reference delay section S0,when the delay value of the actual delay circuit is different from thedelay value of the delay circuit at the time of designing due todiffusion conditions, in-plane variations of a wafer, and so on at thetime of manufacturing a semiconductor memory device.

The delay section S1 is further provided with an INPS terminal, an RSTterminal, CNT <n:0> terminals, MT<m:0> terminals, and an OUTPS terminal.The delay request trigger signal INPS is supplied externally to the INPSterminal. The reset signal RST is supplied externally to the RSTterminal. The CNT <n:0> terminals are connected to the reference delaysection S0 through the bus.

The delay circuit control circuit A6 receives the trigger signal INPS,the reset signal RST, a bus signal HT<0> and an output signal MCNTS,which is an output signal outputted from the delay circuit A7, and acoincidence detection signal MTOUTB outputted from the coincidencedetecting circuit A9. The delay circuit control circuit A6 outputs anoutput signal MDLYI to the delay circuit A7, a reset signal DRST to thedelay circuit A7 and the delay counter circuit A8, and the output signalOUTPS. The output signal OUTPS is a pulse signal corresponding to adelay value obtained by multiplying the delay value of the delay circuitA7 by a constant value. The delay circuit control circuit A6 has a latchsection. The latch section latches the output signal OUTPS in responseto the trigger signal INPS. When the output signal OUTPS is latched andthe bus signal HT<0> is in one of the active state and the inactivestate, the delay circuit control circuit A6 outputs the output signalMDLYI in the other of the active state and the inactive state to thedelay circuit A7.

The delay circuit A7 receives the output signal MDLYI outputted from thedelay circuit control circuit A6, the reset signal DRST, and the bussignal CNT <n:0>, which is a count value outputted from the countercircuit A4. The delay circuit A7 outputs the output signal MCNTS to thedelay circuit control circuit A6 and the delay counter circuit A8, andthe bus signal HT<0>, which is one of the coincidence detection signals.The delay circuit A7 has a first delay value. The delay circuit A7generates a reference delay value based on the first delay value and theadjustment value which is indicated based on the fixed bus signal CNT<n:0>, and delays the output signal MDLYI based on the reference delayvalue, to output the signal MCNTS as the output signal DLYOB, and thebus signal HT<0> as an inversion signal of the output signal DLYOB.

The delay counter circuit A8 receives the output signal MCNTS outputtedfrom the delay circuit A7 and the reset signal DRST outputted from thedelay circuit control circuit A6, and outputs a bus signal HT<m:1> tothe coincidence detecting circuit A9. The delay counter circuit A8 is acounter circuit with a binary counter structure for counting the outputsignal MCNTS as a clock signal CLK, and outputs the count value as thebus signal HT<m:1> to the coincidence detecting circuit A9. The delaycounter circuit A8 retains the output count value (HT<m:1>). When theoutput signal MCNTS changes from one of the active state and theinactive state to the other, the delay counter circuit A8 increments theretained output count value HT<m:1> by one, and outputs the bus signalHT<m:1> to indicate the output count value. A set bus signal MT<m:0> issupplied externally or internally to the MT<m:0> terminals to indicate aset multiplication value set in advance.

The coincidence detecting circuit A9 receives the bus signal HT<m:0>outputted from the delay circuit A7 and the delay counter circuit A8,and the set bus signal MT<m:0>, and outputs the coincidence detectionsignal MTOUTB of a low level when the bus signal HT<m:0> and the set bussignal MT<m:0> are coincident with each other. The value “m” in the bussignal HT<m:0> and the set bus signal MT<m:0> is the number of bits whenthe multiplication value indicating how many times of reference delay isnecessary is binarized. The set multiple value by the set bus signalMT<m:0> indicates a delay value of m times of the reference delay value.The coincidence detecting circuit A9 outputs the coincidence detectionsignal MTOUTB to the delay circuit control circuit A6 when the outputcount value indicated by the bus signal HT<m:0> and the set multiplevalue indicated by the set bus signal MT<m:0> are coincident with eachother. At this time, the delay circuit control circuit A6 outputs theoutput signal OUTPS latched by the latch section, in response to thecoincidence detection signal MTOUTB. Thus, the output signal OUTPS isoutputted to have a delay value of m times of the reference delay valuein response to the trigger signal INPS.

In this way, the semiconductor memory device of the present inventioncan obtain a delay value of m times of the reference delay value as adesired delay value by using the delay section S1, since the referencedelay value is generated by the above reference delay section S0.

FIG. 2 is a circuit diagram showing a configuration of the referencedelay circuit S0 when n is 3. The delay circuit pulse generating circuitA1 in the reference delay circuit S0 includes an AND circuit D1. Thepulse signal PULSEI and the enable signal TDEN are supplied to the ANDcircuit D1. When both of the pulse signal PULSEI and the enable signalTDEN are in the high level, the AND circuit D1 outputs the output signalDLYI of the high level. Otherwise, the AND circuit D1 outputs the outputsignal DLYI of the low level “L”.

The delay circuit A2 in the reference delay circuit S0 includes invertercircuits C1, C2, C3, C4, C29, and C30; PMOS transistors C5, C6, C7, C8,C13, C14, C18, C19, C21, C24, and C26; NMOS transistors C9, C10, C11,C12, C15, C16, C20, C22, C23, C25, and C27; a buffer circuit C17; and anNAND circuit C28. The inverter circuits C1, C2, C3, and C4 receivesignals CNT<3>, CNT<2>, CNT<1>, and CNT<0> of the bus signal CNT<3:0>outputted from the counter circuit A4, and output signals CNTB3, CNTB2,CNTB1, and CNTB0 as inversion signals of the received signals CNT<3>,CNT<2>, CNT<1>, and CNT<0>, respectively. Each source of the PMOStransistors C5, C6, C7, and C8 receives a signal NINL. Drains of thePMOS transistors C5, C6, C7, and C8 output the signal NINL as a signalFLEV in accordance with the signals CNTB3, CNTB2, CNTB1, and CNTB0supplied to the gates of the PMOS transistors. Drains of the NMOStransistors C9, C10, C11, and C12 receive the signal FLEV, respectively.Sources of the NMOS transistors C9, C10, C11, and C12 output the signalFLEV as a signal PINL in accordance with the signals CNT<3>, CNT<2>,CNT<1>, and CNT<0> supplied to the gates of the NMOS transistors C9,C10, C11, and C12, respectively. The source of the PMOS transistor C13is supplied with a power supply voltage VDD, and the gate and drainthereof receive the above signal NINL. The gate of the PMOS transistorC14 is grounded (GND), the source thereof receives the above signalNINL, and the drain thereof outputs the signal NINL as the signal FLEVin accordance with the signal supplied to the gate. The gate of the NMOStransistor C15 is supplied with the power supply voltage VDD, the drainthereof is supplied with the above signal FLEV, and the source thereofoutputs the above signal FLEV as the signal PINL in accordance with thesignal supplied to the gate. The gate and drain of the NMOS transistorC16 are supplied with the above signal PINL, and the source thereof isgrounded (GND).

The buffer circuit C17 receives the output signal DLYI, which is theoutput of the delay circuit pulse generating circuit A1, and outputs asignal DLFI. The source of the PMOS transistor C18 is supplied with thepower supply voltage VDD, and the drain thereof outputs a signal PINP inaccordance with the signal PINL supplied to the gate thereof. The sourceof the NMOS transistor C23 is grounded (GND), and the drain thereof issupplied with a signal NINN. The signal NINN supplied to the drain isoutputted to the source in accordance with the signal NINL supplied tothe gate thereof. The PMOS transistor C19 and the NMOS transistor C20form an inverter (C19 and C20). The source of the PMOS transistor C19 issupplied with the signal PINP, and the source of the NMOS transistor C20is supplied with the signal NINN. The inverter (C19 and C20) outputs asignal DLF2 in accordance with the signal DLF1 supplied to the input ofthe inverter. The PMOS transistor C21 and the NMOS transistor C22 forman inverter (C21 and C22). The source of the PMOS transistor C21 issupplied with the signal PINP, and the source of the NMOS transistor C22is supplied with the signal NINN. The inverter (C21 and C22) outputs asignal DLF3 in accordance with the signal DLF2 supplied to the input.The PMOS transistor C24 and the NMOS transistor C25 form an inverter(C24 and C25). The source of the PMOS transistor C24 is supplied withthe signal PINP, and the source of the NMOS transistor C25 is suppliedwith the signal NINN. The inverter (C24 and C25) outputs a signal DLF4in accordance with the signal DLF3 supplied to the input. The PMOStransistor C26 and the NMOS transistor C27 form an inverter (C26 andC27). The source of the PMOS transistor C26 is supplied with the signalPINP, and the source of the NMOS transistor C27 is supplied with thesignal NINN. The inverter (C26 and C27) outputs a signal DLF5 inaccordance with the signal DLF 4 supplied to the input. The invertercircuit C30 receives the reset signal RST, and outputs a signal DLF6 asan inversion signal of the reset signal RST. The NAND circuit C28 issupplied with the signals DLF5 and DLF6. When both of the signals DLF5and DLF6 are in the high level “H”, the NAND circuit C28 outputs theoutput signal DLYOB of the low level “L” to the determining circuit A3.Otherwise, the NAND circuit C28 outputs the output signal DLYOB of thehigh level “H” to the determining circuit A3. The inverter circuit C29receives the output signal DLYOB, and outputs a signal DLYO as aninversion signal.

The determining circuit A3 in the reference delay circuit S0 includes anAND circuit F1, inverter circuits F2 and F6, CMOS transfer gate circuitsF3 and F4, an NOR circuit F5, and a buffer circuit F7. The AND circuitF1 is supplied with the above pulse signal PULSEI and the above enablesignal TDEN. When both of the pulse signal PULSEI and the enable signalTDEN are in the high level “H”, the AND circuit F1 outputs an outputsignal LT0 of the high level “H”. Otherwise, the AND circuit F1 outputsthe output signal LT0 of the low level “L”. The inverter circuit F2receives the signal LT0, and outputs a signal LT1. The CMOS transfergate circuit F3 transfers the above signal LT0 to output a signal LT2.The CMOS transfer gate circuit F4 is controlled based on the signal LI1and the signal LT2 and transfers the signal DLYOB to output as a signalLT3. When the signals LT1 and LT2 are the low level “L” and the highlevel “H”, respectively, the CMOS transfer gate circuit F4 outputs theoutput signal DLYOB as the signal LT3. The NOR circuit F5 is suppliedwith the above reset signal RST and the signal LT3 from the transfergate circuit F4. When either the reset signal RST or the signal LT3 isthe low level “L”, the NOR circuit F5 outputs a signal LT4 of the highlevel “H”. Otherwise, the NOR circuit F5 outputs the signal LT4 of thelow level “L”. The inverter circuit F6 is supplied with the signal LT4,and outputs the signal LT3. The buffer circuit F7 is supplied with thesignal LT4, and outputs a determination resultant signal DSTE to thecounter circuit control pulse signal generating circuit A5.

The counter circuit control pulse signal generating circuit A5 in thereference delay circuit S0 includes a buffer circuit E1, a NAND circuitE2, inverter circuits E4 and E5, and AND circuits E6 and E7. The buffercircuit E1 is supplied with the above pulse signal PULSEI, and outputs asignal PF1. The NAND circuit E2 is supplied with the signal PF1 and theabove enable signal TDEN. When both of the signal PF1 and the enablesignal TDEN are in the high level “H”, the NAND circuit E2 outputs asignal PF2 of the low level “L”. Otherwise, the NAND circuit E2 outputsthe signal PF2 of the high level “H”. The buffer circuit E3 is suppliedwith the signal PF2, and outputs a signal PF3. The inverter circuit E4receives the signal PF3, and outputs a signal PF4. The inverter circuitE5 receives the determination resultant signal DSTE from the determiningcircuit A3, and outputs a signal PF5 as an inversion signal of thedetermination resultant signal DSTE. The AND circuit E6 is supplied withthe signals PF2 and PF4 and the above enable signal TDEN. When all ofthe signals PF2 and PF4 and the enable signal TDEN are in the high level“H”, the AND circuit E6 outputs a signal PF6 of the high level “H”.Otherwise, the AND circuit E6 outputs the signal PF6 of the low level“L”. The AND circuit E7 is supplied with the signals PF5 and PF6. Whenboth of the signals PF5 and PF6 are in the high level “H”, the ANDcircuit E7 outputs the control pulse signal FFCK of the high level “H”.Otherwise, the AND circuit E7 outputs the control pulse signal FFCK ofthe low level “L”.

The counter circuit A4 in the reference delay circuit S0 includesflip-flop circuits B1, B2, B3, and B4. Each of the flip-flop circuitsB1, B2, B3, and B4 has an inversion data input terminal DB, a clockinput terminal CK, output terminals Q and QB, and a reset terminal RST.The input terminal DB and the output terminal Q are connected. Theterminal CK of the flip-flop circuit B1 is connected to the countercircuit control pulse signal generating circuit A5. The output terminalsQB of the flip-flop circuits B1, B2, and B3 are connected to theterminals CK of the flip-flop circuits B2, B3, and B4 respectively. Theterminal CK of the flip-flop circuit B1 is supplied with the controlpulse signal FFCK from the counter circuit control pulse signalgenerating circuit A5. When the signal level of the above control pulsesignal FFCK shifts to the high level “H”, the flip-flop circuit B1outputs a signal in phase with the signal DB supplied to the inputterminal DB to the output terminal QB as a signal FF1. When the signallevel of the above signal FF1 shifts to the high level “H”, theflip-flop circuit B1 latches the DB data supplied to the input terminalDB, and outputs the bus signal CNT<0> of the bus signal CNT<3:0> to theoutput terminal Q. The terminal CK of the flip-flop circuit B2 issupplied with the output signal FF1 from the flip-flop circuit B1. Whenthe signal level of the above output signal FF1 shifts to the high level“H”, the flip-flop circuit B2 outputs a signal in phase with the signalDB supplied to the input terminal DB to the output terminal QB as asignal FF2. When the signal level of the above signal FF2 shifts to thehigh level “H”, the flip-flop circuit B2 latches the DB data supplied tothe input terminal DB, and outputs the bus signal CNT<L> of the bussignal CNT<3:0> to the output terminal Q. The terminal CK of theflip-flop circuit B3 is supplied with the output signal FF2 from theflip-flop circuit B2. When the signal level of the above output signalFF2 shifts to the high level “H”, the flip-flop circuit B3 outputs asignal in phase with the signal DB supplied to the input terminal DB tothe output terminal QB as a signal FF3. When the signal level of theabove signal FF3 shifts to the high level “H”, the flip-flop circuit B3latches the DB data supplied to the input terminal DB, and outputs thebus signal CNT<2> among the bus signal CNT<3:0> to the output terminalQ. The terminal CK of the flip-flop circuit B4 is supplied with theoutput signal FF3 from the flip-flop circuit B3. When the signal levelof the above output signal FF3 shifts to the high level “H”, theflip-flop circuit B4 latches the DB data supplied to the input terminalDB, and outputs the bus signal CNT<3> among the bus signal CNT<3:0> tothe output terminal Q. The flip-flop circuits B1, B2, B3, and B4 resetthe output of the output terminals Q and QB when the reset terminals RSTof the flip-flop circuits B1, B2, B3, and B4 receive the above resetsignal RST.

FIG. 3 is a circuit diagram showing a structure in the delay section S1in case that n is 3 and m is 3.

The delay circuit control circuit A6 in the delay section S1 includesinverter circuits G1 and G2, NAND circuits G3 and G4, and CMOS transfergate circuits G5 and G6. The inverter circuit G1 is supplied with theabove trigger signal INPS, and outputs a signal SF1 as an inversionsignal of the trigger signal INPS. The inverter circuit G2 receives theabove reset signal RST, and outputs a signal SF2 as an inversion signalof the reset signal RST. The NAND circuits G3 and G4 form a latchsection. The NAND circuit G3 is supplied with the signal SF1 and thereset signal DRST from the NAND circuit G4. When both of the signal SF1and the reset signal DRST are in the high level “H”, the NAND circuit G3outputs the output signal OUTPS of the low level “L” to the outside.Otherwise, the NAND circuit G3 outputs the output signal OUTPS of thehigh level “H” to the outside. The NAND circuit G4 is supplied with theoutput signal OUTPS, the signal SF2, and the coincidence detectionsignal MTOUTB from the coincidence detecting circuit A9. When all of theoutput signal OUTPS, the signal SF2, and the coincidence detectionsignal MTOUTB are in the high level “H”, the NAND circuit G4 outputs thereset signal DRST of the low level “L”. Otherwise, the NAND circuit G4outputs the reset signal DRST of the high level “H”. The CMOS transfergate circuit G5 is supplied with the bus signal HT<0> from the delaycircuit A7 and an output signal MCNTS, which is an inversion signal ofthe bus signal HT<0> from the delay circuit A7, and the sources of theNMOS transistor and PMOS transistor thereof are grounded (GND). When thesignal levels of the bus signal HT<0> and the output signal MCNTS are inthe high level “H” and the low level “L”, respectively, the CMOStransfer gate circuit G5 outputs the output signal MDLYI of the lowlevel “L”. The CMOS transfer gate circuit G6 is supplied with the outputsignal MCNTS from the delay circuit A7 and the bus signal HT<0> from thedelay circuit A7, and the input is supplied with the output signalOUTPS. When the signal levels of the bus signal HT<0> and the outputsignal MCNTS are the low level “L” and the high level “H”, respectively,the CMOS transfer gate circuit G6 outputs the output signal MDLYI.

The delay circuit A7 in the delay section S1 includes a delay circuit H1having the same structure as the delay circuit A2 in the reference delaysection S0. That is, the delay circuit H1 is supplied with the bussignal CNT<3:0> outputted from the counter circuit A4. The delay circuitH1 is supplied with the output signal MDLYI from the delay circuitcontrol circuit A6 as the output signal DLYI. The delay circuit H1 issupplied with the reset signal DRST from the delay circuit controlcircuit A6 as the reset signal RST. The delay circuit H1 outputs theoutput signal MCNTS as the output signal DLYOB, and the bus signal HT<0>as the output signal DLYO.

The delay counter circuit A8 in the delay section S1 includes flip-flopcircuits I1, 12, and 13. Each of the flip-flop circuits I1, 12, and 13has a data input terminal DB, a clock input terminal CK, outputterminals Q and QB, and a reset terminal RST. The input terminal DB andthe output terminal Q are connected. The terminal CK of the flip-flopcircuit I1 is connected to the delay circuit A7. The output terminals QBof the flip-flop circuits I1 and I2 are connected to the terminals CK ofthe flip-flop circuits I2 and I3, respectively. The terminal CK of theflip-flop circuit I1 is supplied with the output signal MCNTS from thedelay circuit A7. When the signal level of the above output signal MCNTSshifts to the high level “H”, the flip-flop circuit I1 outputs a signalin phase with a signal DB supplied to the input terminal DB to theoutput terminal QB as a signal SF6. When the signal level of the abovesignal SF6 shifts to the high level “H”, the flip-flop circuit I1latches the DB data supplied to the input terminal DB, and outputs asthe bus signal HT<1> to the output terminal Q. The terminal CK of theflip-flop circuit I2 is supplied with the signal SF6 from the flip-flopcircuit I1. When the signal level of the above signal SF6 shifts to thehigh level “H”, the flip-flop circuit I2 outputs a signal in phase withthe signal DB supplied to the input terminal DB to the output terminalQB as a signal SF7. When the signal level of the above signal SF7 shiftsto the high level “H”, the flip-flop circuit I2 latches the signal DBsupplied to the input terminal DB, and outputs a bus signal HT<2> to theoutput terminal Q. The terminal CK of the flip-flop circuit I3 issupplied with the output signal SF7 from the flip-flop circuit I2. Whenthe signal level of the above output signal SF7 shifts to the high level“H”, the flip-flop circuit I3 latches the DB data supplied to the inputterminal DB, and outputs a bus signal HT<3> to the output terminal Q.The flip-flop circuits I1, I2, and I3 reset the outputs of the outputterminal Q and QB when the reset terminals RST of the flip-flop circuitsI1, I2, and I3 receive the above reset signal DRST.

The coincidence detecting circuit A9 in the delay section S1 includesexclusive NOR circuits J1, J2, J3, and J4, and a NAND circuit J5. Theexclusive NOR circuit J1 is supplied with a set bus signal MT<0> of aset bus signal MT<3:0>, and the bus signal HT<0>. When the set bussignal MT<0> and the bus signal HT<0> are coincident with each other,the exclusive NOR circuit J1 outputs a signal XT0 of the high level “H”.Otherwise, the exclusive NOR circuit J1 outputs the signal XT0 of thelow level “L”. The exclusive NOR circuit J2 is supplied with a set bussignal MT<1> of the set bus signal MT<3:0>, and the bus signal HT<1>.When the signal levels of the set bus signal MT<1> and the bus signalHT<1> are coincident with each other, the exclusive NOR circuit J2outputs a signal XT1 of the high level “H”. Otherwise, the exclusive NORcircuit J2 outputs the signal XT1 of the low level “L”. The exclusiveNOR circuit J3 is supplied with a set bus signal MT<2> of the set bussignal MT<3:0>, and the bus signal HT<2>. When the signal levels of theset bus signal MT<2> and the bus signal HT<2> are coincident with eachother, the exclusive NOR circuit J3 outputs a signal XT2 of the highlevel “H”. Otherwise, the exclusive NOR circuit J3 outputs the signalXT2 of the low level “L”. The exclusive NOR circuit J4 is supplied witha set bus signal MT<3> among the set bus signal MT<3:0>, and the bussignal HT<3>. When the signal levels of the set bus signal MT<3> and thebus signal HT<3> are coincident with each other, the exclusive NORcircuit J4 outputs a signal XT3 of the high level “H”. Otherwise, theexclusive NOR circuit J4 outputs the signal XT3 of the low level “L”.The NAND circuit J5 is supplied with the signals XT0, XT1, XT2, and XT3.When all of the signals XT0, XT1, XT2, and XT3 are in the high level“H”, the NAND circuit J5 outputs the coincidence detection signal MTOUTBof the low level “L” to the delay circuit control circuit A6. Otherwise,the NAND circuit J5 outputs the coincidence detection signal MTOUTB ofthe high level “H” to the delay circuit control circuit A6.

Next, an operation of the semiconductor memory device according to thefirst embodiment of the present invention will be described withreference to FIGS. 4A to 4K and FIGS. 5A to 5G. FIGS. 4A to 4K aretiming charts showing an operation of the reference delay section S0.

First, as an initialization operation, the reset signal RST of the highlevel is supplied as a one-shot pulse to the delay circuit A2, thedetermining circuit A3, and the counter circuit A4, to perform reset inthe delay circuit A2, the determining circuit A3, and the countercircuit A4. Through the above reset operation, the delay circuit A2outputs the output signal DLYOB of the high level “H”; the determiningcircuit A3 outputs the determination resultant signal DSTE of the lowlevel “L”; and the counter circuit A4 outputs the bus signal CNT<n:0> ofthe low level “L”.

When the bus signal CNT<n:0> of the low level “L” is supplied from thecounter circuit A4 to the delay circuit A2, the signals supplied to thegates of the PMOS transistors C5 to C8 become the high level “H”, andthe signals supplied to the gates of the NMOS transistors C9 to C12become the low level “L” in the delay circuit A2. At this time, thesignal PINL used to determine a delay in the delay circuit A2 gets thelow level, and drive performance of the PMOS transistor C18 isincreased. Additionally, the signal NINL gets the high level, and driveperformance of the NMOS transistor S23 is increased. Consequently, atime period for which the delay circuit A2 receives the output signalDLYI from the delay circuit pulse generating circuit A1 to output theoutput signals DLYO and DLYOB, namely, a delay time of the delay circuitA2 is minimized.

Next, the enable signal TDEN generated through the external-command isset to the high level “H” and supplied to the delay circuit pulsegenerating circuit A1, the determining circuit A3, and the countercircuit control pulse signal generating circuit A5. After that, thepulse signal PULSEI is supplied from the high-performance tester and soon (not shown) to the semiconductor memory device and is delivered tothe delay circuit pulse generating circuit A1, the determining circuitA3, and the counter circuit control pulse signal generating circuit A5.The pulse width of the pulse signal PULSEI in the high level “H”,indicates a set delay value, which is a delay value to be set to thedelay circuit A2. Here, in an initialization state, the pulse width ofthe pulse signal PULSEI is set to a value larger than a delay value inthe initialization state. That is, the adjustment range of the delaycircuit A2 needs to be set so as to permit adjustment to a desired delayvalue in a range between the expected fastest and slowest delay values,a difference between which is caused due to the diffusion conditions andthe in-plane variations of a wafer, and so on.

The delay circuit pulse generating circuit A1 outputs the output signalDLYI in phase with the pulse signal PULSEI to the delay circuit A2 inresponse to the pulse signal PULSEI and the enable signal TDEN. Thedelay circuit A2 delays the output signal DLYI with a certain delayvalue, and outputs the delayed output signal DLYI as the output signalsDLYO and DLYOB. The determining circuit A3 latches the output signalDLYOB in response to the falling edge of the pulse signal PULSEI.

Since the signal level of the output signal DLYI and that of the outputsignal DLYOB are not coincident with each other during the first stage,the determining circuit A3 outputs the determination resultant signalDSTE of the low level “L”. When the determination resultant signal DSTEis in the low level “L”, the adjustment of the delay is not completed.In this case, the counter circuit control pulse generating circuit A5takes an operation state, and outputs the control pulse signal FFCK ofthe high level “H” as a one-shot pulse after a delay by an internalbuffer circuit and so on, in response to the falling edge of the pulsesignal PULSEI at a time T1.

The counter circuit A4 receives the control pulse signal FFCK to controlthe flip-flops in the counter circuit A4 operate, and outputs the bussignal CNT<0> of the high level “H”. When the bus signal CNT<0> of thehigh level “H” is supplied to the delay circuit A2, the signals suppliedto the gates of the PMOS transistor C8 and the NMOS transistor C12 shiftto the low level “L” and the high level “H” in the delay circuit A2.Because of the transition, the signal level of the signal PINL used todetermine the delay in the delay circuit A2 is slightly increased, andthe signal level of the signal NINL is slightly decreased. As a result,the delay time for which the delay circuit A2 receives the output signalDLYI from the delay circuit pulse generating circuit A1 to output theoutput signals DLYO and DLYOB is slightly extended. The setting of astep time of the above delay time is performed by adjusting the driveperformance of the PMOS transistors C5 to C8 and the NMOS transistors C9to C12 in the delay circuit A2 in advance. The above transition isperformed in a time period from the time T1 showing the first fallingedge of pulse signal PULSEI to a time showing the next (second) fallingedge of the pulse signal PULSEI.

Similarly, the above transition is performed a time period from a timeT2 showing the second falling edge of the pulse signal PULSEI to a timeshowing the third rising edge of the pulse signal PULSEI. Next, thetransition is performed in a time period from a time T3 showing thethird falling edge of the pulse signal PULSEI to a time showing thefourth rising edge of the pulse signal PULSEI. Then, the transition isperformed in a time period from a time T4 showing the fourth fallingedge of the pulse signal PULSEI to a time showing the fifth rising edgeof the pulse signal PULSEI. Thus, by repeating the above transition, thedelay value of the delay circuit A2 gets gradually closer to the pulsewidth “H” of the pulse signal PULSEI supplied to the delay circuit A2.At the time T4, the delay value of the delay circuit A2 is the samevalue as the delay value shown by the pulse signal PULSEI.

At this time, the determining circuit A3 latches the output signal DLYOBof the high level “H” from the delay circuit A2, and outputs thedetermination resultant signal DSTE of the high level “H”. That is, thedetermining circuit A3 outputs the determination resultant signal DSTEof the high level “H”, when determining that the output signal DLYOBfrom the delay circuit A2 is in the high level “H” in response to thefalling edge of the pulse signal PULSEI when the enable signal TDEN isin the high level “H”. In this case, the counter circuit control pulsesignal generating circuit A5 does not output the control pulse signalFFCK of the high level “H” as a one-shot pulse. Therefore, the countercircuit A4 stops the operation.

Through the above operation, a value of the CNT<3:0> is settled (fixed,set) as a reference delay of the delay circuit A2. The settled (fixed,set) delay value of the delay circuit A2 is hereinafter referred to as areference delay value. After that, the signal level of the enable signalTDEN is changed to the low level “L” through the external command.

FIGS. 5A to 5G are timing charts showing an operation of the delaysection S1. As shown in FIGS. 5A to 5G, the operation of the delaysection S1 will be described when the bus signal CNT<n:0> as a delaydata is b′011 in the binary, and the set bus signal MT<m:0> is b′100 inthe binary to indicate how many times of the delay value of the delaycircuit A2 is necessary.

First, as the initialization operation, the reset signal RST of the highlevel as a one-shot pulse is supplied to the delay circuit controlcircuit A6. At this time, the delay circuit control circuit A6 receivesthe reset signal RST to supply the reset signal DRST to the delaycircuit A7 and the delay counter circuit A8, for resetting the delaycounter circuit A8. Through the above reset operation, the delay circuitA7 outputs the bus signal HT<0> of the low level “L” as the outputsignal DLYO of the delay circuit A7, and outputs the output signal MCNTSof the high level “H” as the output signal DLYOB of the delay circuitA7.

Here, the signal level of the reset signal DRST is latched by the NANDcircuits G3 and G4 of the delay circuit control circuit A6 and outputtedas the signal of the high level “H”. That is, the delay circuit A7 stopsoperation. Additionally, the delay counter circuit A8 is also in a resetstate. Therefore, the signal level of the bus signal HT<m:0> is the lowlevel “L”. At this time, since the value indicated by the bus signalHT<2> and the value indicated by the set bus signal MT<2> are different,the coincidence detecting circuit A9 sets the signal level of the signalXT2 outputted from the exclusive NOR circuit J3 to the low level “L”,and the signal level of the coincidence detection signal MTOUTBoutputted from the NNAD circuit J5 to the high level “H”. In this state,if the trigger signal INPS of the high level as the one-shot pulse issupplied to the delay circuit control circuit A6, the trigger signalINPS of the high level “H” is latched by the NAND circuits G3 and G4 ofthe delay circuit control circuit A6, so that the signal level of theoutput signal OUTPS is set to the high level “H”, and the signal levelof the reset signal DRST is set to the low level “L”. That is, the delaycircuit A7 enters an operation permitting state.

Since the signal level of the bus signal HT<0> is the low level “L” andthe signal level of the output signal MCNTS is the high level “H”, theCMOS transfer gate circuit G6 outputs the output signal OUPTS of thehigh level “H” as the output signal MDLYI. The output signal MDLYI issupplied to the delay circuit A7 as the signal DLYI. The delay circuitA7 recognizes the delay value (reference delay value) of the delaycircuit A2 in the above reference delay section S0 from the bus signalCNT<3:0> from the counter circuit A4 in the above reference delaysection S0. The delay circuit A7 delays the output signal MDLYI of thehigh level “H” with the same delay value as the reference delay value,and sets the signal level of the bus signal HT<0> to the high level “HH”as the output signal DLYO of the delay circuit A7, and the signal levelof the output signal MCNTS to the low level “L” as the output signalDLYOB of the delay circuit A7. In response to the transition of the bussignal HT<0> to the high level “H” and the output signal MCNTS to thelow level “L”, the CMOS transfer gate circuit G6 of the delay circuitcontrol circuit A6 takes an OFF state. Instead, the COMS transfer G5takes an ON state. Thus, the delay circuit control circuit A6 sets thesignal level of the output signal MDLYI to the low level “L” as the GNDlevel. The delay circuit A7, after delaying the output signal MDLYI ofthe low level “L” with the reference delay value, sets the signal levelof the bus signal HT<0> to the low level “L”, and the signal level ofthe output signal MCNTS to the high level “H”. The transition of thesignal level of the output signal MCNTS to the high level “H” starts theflip-flop circuit I1 of the delay counter circuit A8, so that the signallevel of the bus signal HT<1> is set to the high level “H”. In responseto the transitions of the bus signal HT<0> to the low level “L” and theoutput signal MCNTS to the high level “H”, the CMOS transfer gatecircuit G5 of the delay circuit control circuit A6 takes the OFF state,and the CMOS transfer gate circuit G6 takes the ON state. Thus, the CMOStransfer gate circuit G6 of the delay circuit control circuit A6 outputsthe output signal OUTPS of the high level “H” as the output signalMDLYI. The output signal MDLYI is supplied to the delay circuit A7 asthe signal DLYI.

By repeating the above operation, the delay counter circuit A8 counts upfor every delay value of two times of the reference delay value. Thesignal level of the bus signal HT<0> as the output of the delay circuitA7 is switched from the low level “L” to the high level “H” to the lowlevel “L” in units of the reference delay values. This is the same aschange of a least significant bit of a count value that indicates thenumber of times of the delay based on the reference delay value. The bussignals HT<0> as the output of the delay circuit A7 and HT<m:1> as theoutput of the counter circuit indicate a multiplication of the referencedelay value by a constant.

As shown in FIGS. 5A to 5G, the value shown by the bus signal HT<m:0> isthe same as b′100 shown by the set bus signal MT<m:0>. That is, thevalue shown by the bus signal HT<2> and the value shown by the set bussignal MT<2> are the same. At this time, the coincidence detectingcircuit A9 sets the signal levels of the signals XT0, XT1, XT2, and XT3outputted from the exclusive NOR circuits J1, J2, J3, and J4 to the highlevel H”, and sets the signal level of the coincidence detection signalMTOUTB to the low level “L” as the detection resultant signal outputtedfrom the NAND circuit J5. In this state, if the coincidence detectionsignal MTOUTB of the low level “L” is supplied to the delay circuitcontrol circuit A6, the signal level latched by the NAND circuits G3 andG4 of the delay circuit control circuit A6 is reset. Also, the signallevel of the output signal OUTPS is set to the low level “L”, and thesignal level of the reset signal DRST is set to the high level “H”. Thatis, the same state as the initialization state is generated.

Through the above operation, it is possible to generate the outputsignal OUTPS of the high level “H” for a time period corresponding tothe multiplication of the reference delay value by a value shown by theset bus signal MT<m:0>.

In the example shown in FIG. 5, it is possible to generate the outputsignal OUTPS having a pulse width of four times of the reference delayvalue. By using the above transition, a desired operation can beperformed after a requested delay time.

As described above, the semiconductor memory device of the presentinvention can eliminate a difference between the delay value of thedelay circuit at the time of designing and the delay value of the actualdelay circuit through the use of the above reference delay section S0,even when the delay value of the actual delay circuit is different fromthe delay value of the delay circuit at the time of designing due todiffusion conditions and in-plane variations of a wafer and so on, atthe time of manufacturing the semiconductor memory device. That is tosay, in the reference delay section S0, the delay circuit pulsegenerating circuit A1 outputs the output signal DLYI in the active stateto the delay circuit A2, when the pulse signal PULEI is in the activestate “H” when the delay circuit pulse generating circuit A1 receivesthe enable signal TDEN.

The determining circuit A3 outputs the comparison result DSTE toindicate the non-coincidence between the second delay value and the setdelay value, when the pulse width showing the active state “H” of thepulse signal PULSEI and the pulse width showing the active state “H” ofthe signal DLYOB are not coincident with each other. At this time, thecounter circuit control pulse signal generating circuit A5 outputs thecontrol pulse signal FFCK in the active state “H”. Also, the countercircuit A4 increments a retained adjustment value by one, and outputsthe bus signal CNT<n:0> to indicate the incremented adjustment value.Additionally, the delay circuit A2 generates the second delay valuebased on the first delay value and the adjustment value shown by the bussignal CNT<n:0>, and delays the output signal DLYI with the second delayvalue to output the output signal DLYOB.

On the other hand, the determining circuit A3 outputs the comparisonresult DSTE to indicate the coincidence between the second delay valueand the set delay value, when the pulse width showing the active state“H” of the pulse signal PULEI and the pulse width showing the activestate “H” of the signal DLYOB are coincident with each other. At thistime, the counter circuit control pulse signal generating circuit A5outputs the control pulse signal FFCK in the inactive state “L” in orderto fix the adjustment value shown by the bus signal CNT<n:0> outputtedfrom the counter circuit A4. The counter circuit A4 regards the retainedadjustment value as the fixed value, and outputs the bus signal CNT<n:0>to indicate the retained adjustment value. “In this case, the delaycircuit A2 generates the reference delay value based on the first delayvalue and the above fixed adjustment value indicated by the bus signalCNT<n:0>, and delays the output signal DLYI with the reference delayvalue to output the output signal DLYOB. Thus, in the semiconductormemory device of the present invention, since the reference delay valueis generated by using the above reference delay section S0, it ispossible to eliminate the difference between the delay value of thedelay circuit at the time of designing and the delay value of the actualdelay circuit. Also, in the semiconductor memory device of the presentinvention, since the reference delay value is generated by using theabove reference delay section S0, it is possible to obtain the delayvalue of m times of the reference delay value as a desired delay valuethrough the use of the delay section S1.

That is, in the delay section S1, the delay circuit A7 having the sameconfiguration as the delay circuit A2 generates the reference delayvalue based on the first delay value and the above fixed adjustmentvalue indicated by the bus signal CNT<n:0>, and delays the output signalMDLYI with the reference delay value to output the signal MCNTS as theoutput signal DLYOB, and the bus signal HT<0> as an inversion signal ofthe output signal DLYOB. The latch sections G3 and G4 of the delaycircuit control circuit A6 latches the output signal OUTPS in responseto the trigger signal INPS. When the output signal OUTPS is latched andthe bus signal HT<0> is in one of the active state “H” and the inactivestate “L”, the delay circuit control circuit A6 outputs the outputsignal MDLYI in the other state of the active state “H” and the inactivestate “L” to the delay circuit A7. When the output signal MCNTS changesfrom one state of the active state “H” and the inactive state “L” to theother state, the delay counter circuit A8 increments the retained outputcount value HT<m:1> by one, and outputs the bus signal HT<m:1> toindicate the incremented output count value. The coincidence detectingcircuit A9 receives the bus signal HT<0> from the delay circuit A7 andthe bus signal HT<m:1> from the delay counter circuit A8, and issupplied with the set bus signal MT<m:0> indicating a set multiplicationvalue, which is a delay value of m times of the reference delay value.When the output count value indicated by the bus signal HT<m:0> and theset multiplication value indicated by the set bus signal MT<m:0> arecoincident with each other, the coincidence detecting circuit A9 outputsthe coincidence detection signal MTOUTB to the delay circuit controlcircuit A6. At this time, the delay circuit control circuit A6 outputsthe output signal OUTPS latched by the latch sections G3 and G4 inresponse to the coincidence detection signal MTOUTB.

In this way, in the semiconductor memory device of the presentinvention, it is possible to obtain a delay value of m times of thereference delay value as a desired delay value through the use of thedelay section S1.

Second Embodiment

FIG. 6 is a block diagram showing a configuration of the semiconductormemory device according to the second embodiment of the presentinvention. In the second embodiment, the same description as the firstembodiment is omitted.

The semiconductor memory device in the second embodiment has a referencedelay circuit DLC corresponding to the reference delay section S0 in thefirst embodiment, and delay sections DL0, DL1, . . . , and DLscorresponding to the delay section S1 in the first embodiment. Here, “s”of the DLs shows the number of delay circuits requiring the referencedelay value.

As in the reference delay section S0 in the first embodiment, thereference delay section DLC receives the pulse signal PULSEI, the enablesignal TDEN, and the reset signal RST, and outputs the bus signalCNT<n:0> to the delay sections DL0, DL1, . . . , and DLs. As in thedelay section S1 in the first embodiment, the delay sections DL0, Dl1, .. . , and DLs respectively receive trigger signals INPS0, INPS1, andINPSs as the above trigger signals, and MT1<m:0> . . . , and MTs<m:0> asthe set bus signals, and receive the reset signal RST, the bus signalCNT<n:0>, and set bus signal MT0<m:0> in common. The delay section DL0,Dl1, . . . , and DLs output output signals OUTPS0, OTUPS1, . . . , andOUTPSs as the output signals OUTPS, respectively.

The configuration of the reference delay section DLC is the same as thatof the reference delay section S0 in the first embodiment. For thisreason, components of the reference delay section DLC are referred to asDLC/A1 to A4, and signals inputted and outputted to and from thecomponents used only in the reference delay section DLC are referred toas DLC/“signal name”. The configuration of each of the delay sectionsDL0, DL1, . . . , and DLs is the same as that of the delay section S1 inthe first embodiment. For this reason, names of components of the delaysections DL0, Dl1, . . . , and DLs are referred to as DL0/A6 to A9,DL1/A6 to A9, . . . , and DLs/A6 to A9, respectively. Signals inputtedand outputted to and from the components used only in the delay sectionsDL0, DL1, . . . , and DLs are referred to as DL0/“signal name”,DL1/“signal name”, . . . , and DLs/“signal name”, respectively.

Next, an operation of the semiconductor memory device according to thesecond embodiment of the present invention will be described withreference to FIGS. 7A to 7G, FIGS. 8 a to 8G, and FIGS. 9A to 9G.Description is omitted on an operation of the reference delay sectionDLC, which is the same as that of the reference delay section S0 (seeFIG. 4). In this case, the bus signal CNT<n:0> is fixed after generationof the reference delay value.

FIGS. 7A to 7G are timing charts showing the operation of the delaysection DL0. As shown in FIGS. 7A to 7G, the operation of the delaysection DL0 will be described when the bus signal CNT<n:0> is “b′011” inthe binary and the set bus signal MT0<m:0> is “b′100” in the binary. Inthis case, a value shown by the bus signal HT<m:0> is the same as b′100shown by the set bus signal MT0<m:0>, as shown in FIGS. 7A to 7G.

Through the above operation, it is possible to generate the outputsignal OUTPS having the pulse width of the high level “H” as a delayvalue, which is obtained by multiplying the reference delay value by amultiplication value indicated by the set bus signal MT0<m:0>. In theexample shown in FIGS. 7A to 7G, it is possible to generate the outputsignal OUTPS having as the pulse-width, a delay time of five times ofthe reference delay value.

FIGS. 8A to 8G are timing charts showing the operation of the delaysection DL1. As shown in FIGS. 8A to 8G, the operation of the delaysection DL1 will be described when the bus signal NCT<n:0> is “b′011” inthe binary, and the set bus signal MT1<m:0> is “b′011” in the binary. Inthis case, a value shown by the bus signal HT<m:0> is the same as b′100shown by the set bus signal MT1<m:0>, as shown in FIGS. 8A to 8G.

Through the above operation, it is possible to generate the outputsignal OUTPS having the pulse width of the high level “H” as a delayvalue, which is obtained by multiplying the reference delay value by amultiplication value indicated by the set bus signal MT1<m:0>. In theexample shown in FIGS. 8A to 8G, it is possible to generate the outputsignal OUTPS having as the delay time, the pulse width of three times ofthe reference delay value.

FIGS. 9A to 9G are timing charts showing the operation of the delaysection DLs. Referring to FIGS. 9A to 9G, the operation of the delaysection DLs will be described when the above bus signal CNT<n:0> is“b′011” in the binary, and the set bus signal MTs<m:0> is “b′110” in thebinary. In this case, a value indicated by the bus signal HT<m:0> is thesame as b′110 indicated by the set bus signal MTs<m:0>, as shown inFIGS. 9A to 9G.

Through the above operation, it is possible to generate the outputsignal OUTPS having the pulse width of the high level “H” as a delayvalue, which is obtained by multiplying the reference delay value by amultiplication value indicated by the set bus signal MTs<m:0>. In theexample shown in FIGS. 9A to 9G, it is possible to generate the outputsignal OUTPS having as a delay time, the pulse width of six times of thereference delay value.

In this way, in the semiconductor memory device of the presentinvention, the set multiplication values indicated by the set bussignals MT0<m:0>, Mt1<m:0>, . . . , and MTs<m:0> in the plurality ofdelay sections DL0, DL1, . . . , and DLs may be different from eachother.

It should be noted that the semiconductor memory device of the presentinvention is not limited to the above circuit configuration. Forexample, the counter circuit A4 in the reference delay circuit S0 mayinclude a fuse circuit.

As described above, the semiconductor memory device of the presentinvention can eliminate the difference between the delay value of thedelay circuit at the time of designing and the delay value of the actualdelay circuit.

Also, the present invention is applicable to semiconductor memorydevices such as a DRAM, an SRAM, and so on.

1. A semiconductor device comprises: a reference delay section having afirst delay value and configured to delay a first signal by a referencedelay value obtained from said first delay value and an adjustment valuewhile changing said adjustment value, and to fix said adjustment valuewhen said first signal and the delayed first signal meet a predeterminedcondition; and a delay section having a second delay value, andconfigured to generate an output signal based on a summation of thefixed adjustment value and said second delay value, and a setmultiplication value in response to a trigger signal such that saidoutput signal in an active state for a period corresponding to said setmultiplication value.
 2. The semiconductor device according to claim 1,wherein said predetermined condition is coincidence of a phase of saidfirst signal and a phase of said delayed first signal.
 3. Thesemiconductor device according to claim 1, wherein said reference delaysection comprises: a control pulse signal generating circuit configuredto generate a clock pulse signal when said first signal and the delayedfirst signal do not meet said predetermined condition; and a countercircuit configured to count said clock pulse signal to change saidadjustment value.
 4. The semiconductor device according to claim 3,wherein said control pulse signal generating circuit stops thegeneration of said clock pulse signal when said first signal and thedelayed first signal meet said predetermined condition, and said countercircuit holds and fixes said adjustment value when said clock pulsesignal is not supplied from said control pulse signal generatingcircuit.
 5. The semiconductor device according to claim 1, wherein saidsecond delay value is same as said first delay value.
 6. Thesemiconductor device according to claim 1, wherein said delay sectioncomprises: a control circuit configured to hold said output signal tosaid active state in response to said trigger signal, and to reset saidoutput signal to an inactive state when the summation of the fixedadjustment value and said second delay value is equal to said setmultiplication value.
 7. The semiconductor device according to claim 6,wherein said delay section comprises: a delay circuit configured todelay said output signal by the summation of the fixed adjustment valueand said second delay value; a delay counter configured to count anumber of times of the delay by said delay circuit; and a coincidencedetection circuit configured to generate a coincidence signal whendetecting coincidence of a count value of said delay counter and saidset multiplication value, and said control circuit resets said outputsignal to the inactive state in response to said coincidence signal. 8.The semiconductor device according to claim 1, further comprising: aplurality of said delay sections, wherein said reference delay sectionoutputs the fixed adjustment value to said plurality of delay sections,and said plurality of delay sections receives a plurality of said setmultiplication values which are different from each other.